Grouping of image frames in video coding

ABSTRACT

A method for encoding a video sequence comprising an independent sequence of image frames, wherein at least one reference image frame is predictable from at least one previous image frame that is earlier than the previous reference image frame in decoding order. An indication of at least one image frame is encoded into the video sequence, which indicated image frame is the first image frame, in decoding order, of the independent sequence, said at least one reference image frame being included in the sequence. In the decoding phase, the indication of at least one image frame is decoded from the video sequence, and the decoding of the video sequence is started from said first image frame of the independent sequence, whereby the video sequence is decoded without prediction from any image frame decoded prior to said first image frame.

RELATED PATENT DOCUMENTS

This application is a continuation of U.S. patent application Ser. No. 10/306,942 filed on Nov. 29, 2002 now U.S. Pat. No. 7,894,521 which is incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

The invention relates to the grouping of multimedia files, particularly video files and particularly in connection with streaming.

BACKGROUND OF THE INVENTION

The term ‘streaming’ refers to simultaneous sending and playback of data, typically multimedia data, such as audio and video files, in which the recipient may begin data playback already before all the data to be transmitted has been received. Multimedia data streaming systems comprise a streaming server and terminal devices that the recipients use for setting up a data connection, typically via a telecommunications network, to the streaming server. From the streaming server the recipients retrieve either stored or real-time multimedia data, and the playback of the multimedia data can then begin, most advantageously almost in real-time with the transmission of the data, by means of a streaming application included in the terminal.

From the point of view of the streaming server, the streaming may be carried out either as normal streaming or as progressive downloading to the terminal. In normal streaming the transmission of the multimedia data and/or the data contents are controlled either by making sure that the bit rate of the transmission substantially corresponds to the playback rate of the terminal device, or, if the telecommunications network used in the transmission causes a bottleneck in data transfer, by making sure that the bit rate of the transmission substantially corresponds to the bandwidth available in the telecommunications network. In progressive downloading the transmission of the multimedia data and/or the data contents do not necessarily have to be interfered with at all, but the multimedia files are transmitted as such to the recipient, typically by using transfer protocol flow control. The terminals then receive, store and reproduce an exact copy of the data transmitted from the server, which copy can then be later reproduced again on the terminal without needing to start a streaming again via the telecommunications network. The multimedia files stored in the terminal are, however, typically very large and their transfer to the terminal is time-consuming, and they require a significant amount of storage memory capacity, which is why a normal streaming is often preferred.

The video files in multimedia files comprise a great number of still image frames, which are displayed rapidly in succession (of typically 15 to 30 frames per s) to create an impression of a moving image. The image frames typically comprise a number of stationary background objects, determined by image information which remains substantially unchanged, and few moving objects, determined by image information that changes to some extent. The information comprised by consecutively displayed image frames is typically largely similar, i.e. successive image frames comprise a considerable amount of redundancy. The redundancy appearing in video files can be divided into spatial, temporal and spectral redundancy. Spatial redundancy refers to the mutual correlation of adjacent image pixels, temporal redundancy refers to the changes taking place in specific image objects in subsequent frames, and spectral redundancy to the correlation of different colour components within an image frame.

To reduce the amount of data in video files, the image data can be compressed into a smaller form by reducing the amount of redundant information in the image frames. In addition, while encoding, most of the currently used video encoders downgrade image quality in image frame sections that are less important in the video information. Further, many video coding methods allow redundancy in a bit stream coded from image data to be reduced by efficient, lossless coding of compression parameters known as VLC (Variable Length Coding).

In addition, many video coding methods make use of the above-described temporal redundancy of successive image frames. In that case a method known as motion-compensated temporal prediction is used, i.e. the contents of some (typically most) of the image frames in a video sequence are predicted from other frames in the sequence by tracking changes in specific objects or areas in successive image frames. A video sequence always comprises some compressed image frames the image information of which has not been determined using motion-compensated temporal prediction. Such frames are called INTRA-frames, or I-frames. Correspondingly, motion-compensated video sequence image frames predicted from previous image frames, are called INTER-frames, or P-frames (Predicted). The image information of P-frames is determined using one I-frame and possibly one or more previously coded P-frames. If a frame is lost, frames dependent on it can no longer be correctly decoded.

An I-frame typically initiates a video sequence defined as a Group of Pictures (GOP), the P-frames of which can only be determined on the basis of the I-frame and the previous P-frames of the GOP in question. The next I-frame begins a new group of pictures GOP, the image information comprised by which cannot thus be determined on the basis of the frames of the previous GOP. In other words, groups of pictures are not temporally overlapping, and each group of picture can be decoded separately. In addition, many video compression methods employ bi-directionally predicted B-frames (Bi-directional), which are set between two anchor frames (I- and P-frames, or two P-frames) within a group of pictures GOP, the image information of a B-frame being predicted from both the previous anchor frame and the one succeeding the B-frame. B-frames therefore provide image information of higher quality than P-frames, but typically they are not used as anchor frames, and therefore their removal from the video sequence does not degrade the quality of subsequent images. However, nothing prevents B-frames from being used as anchor frames as well, only in that case they cannot be removed from the video sequence without deteriorating the quality of the frames dependent on them.

Each video frame may be divided into what are known as macroblocks that comprise the colour components (such as Y, U, V) of all pixels of a rectangular image area. More specifically, a macroblock consists of at least one block per colour component, the blocks each comprising colour values (such as Y, U or V) of one colour level in the image area concerned. The spatial resolution of the blocks may differ from that of the macroblocks, for example U- and V-components may be displayed using only half of the resolution of Y-component. Macroblocks can be further grouped into slices, for example, which are groups of macroblocks that are typically selected in the scanning order of the image. Temporal prediction is typically carried out in video coding methods block- or macroblock-specifically, instead of image-frame-specifically.

To allow for flexible streaming of video files, many video coding systems employ scalable coding in which some elements or element groups of a video sequence can be removed without affecting the reconstruction of other parts of the video sequence. Scalability is typically implemented by grouping the image frames into a number of hierarchical layers. The image frames coded into the image frames of the base layer substantially comprise only the ones that are compulsory for the decoding of the video information at the receiving end. The base layer of each group of pictures GOP thus comprises one I-frame and a necessary number of P-frames. One or more enhancement layers can be determined below the base layer, each one of the layers improving the quality of the video coding in comparison with an upper layer. The enhancement layers thus comprise P- or B-frames predicted on the basis of motion-compensation from one or more upper layer images. The frames are typically numbered according to an arithmetical series.

In streaming, transmission bit rate must be controllable either on the basis of the bandwidth to be used or the maximum decoding or bit rate value of the recipient. Bit rate can be controlled either at the streaming server or in some element of the telecommunications network, such as an Internet router or a base station of a mobile communications network. The simplest means for the streaming server to control the bit rate is to leave out B-frames having a high information content from the transmission. Further, the streaming server may determine the number of scalability layers to be transmitted in a video stream, and thus the number of the scalability layers can be changed always when a new group of pictures GOP begins. It is also possible to use different video sequence coding methods. Correspondingly, B-frames, as well as other P-frames of the enhancement layers, can be removed from the bit stream in a telecommunications network element.

The above arrangement involves a number of drawbacks. Many coding methods, such as the coding according to the ITU-T (International Telecommunications Union, Telecommunications Standardization Sector) standard H.263, are familiar with a procedure called reference picture selection. In reference picture selection at least a part of a P-image has been predicted from at least one other image than the one immediately preceding the P-image in the time domain. The selected reference image is signalled in a coded bit stream or in bit stream header fields image-, image-segment- (such as a slice or a group of macroblocks), macroblock-, or block-specifically. The reference picture selection can be generalized such that the prediction can also be made from images temporally succeeding the image to be coded. Further, the reference picture selection can be generalized to cover all temporally predicted frame types, including B-frames. Since it is possible to also select at least one image preceding an I-image that begins a group of pictures GOP as the reference image, a group of pictures employing reference picture selection cannot necessarily be decoded independently. In addition, the adjusting of scalability or coding method in the streaming server or a network element becomes difficult, because the video sequence must be decoded, parsed and buffered for a long period of time to allow any dependencies between different image groups to be detected.

A further problem relates to detection of image frames from which a decoder can start the decoding process. The detection is useful for multiple purposes. For example, an end-user may wish to start browsing a video file from the middle of a video sequence. Another example relates to starting the reception of a broadcast or multicast video transmission from the middle of the video transmission. A third example relates to on-demand streaming from a server and occurs when an end-user wishes to start playback from a certain position of a stream.

BRIEF DESCRIPTION OF THE INVENTION

Now there is invented an improved method and equipment implementing the method, that enable detection of image frames from which a decoder can start the decoding process. Various aspects of the invention include methods, a video encoder, a video decoder, and computer programs that are characterized by what is stated in the independent claims. The preferred embodiments of the invention are disclosed in the dependent claims.

The invention is based on the idea of encoding a video sequence comprising an independent sequence of image frames, wherein at least one reference picture is predictable from at least one previous image frame that is earlier than the previous reference image frame in decoding order. An indication of at least one image frame is encoded into the video sequence, which indicated image frame is the first picture, in decoding order, of the independent sequence, said at least one reference image frame being included in the sequence. Respectively, in the decoding phase, the indication of at least one image frame is decoded from the video sequence, and the decoding of the video sequence is started from said first image frame of the independent sequence, whereby the video sequence is decoded without prediction from any image frame decoded prior to said first image frame.

Consequently, the idea of the present invention is to determine an initiation picture in an independently decodable group of pictures, whereby in the decoding phase any picture prior to said initiation picture is defined as unusable for reference. Accordingly, after decoding the initiation picture, all following pictures of the independently decodable sequence can be decoded without prediction from any picture decoded prior to said initiation picture.

According to an embodiment, the indication is encoded into the video sequence as a separate flag included in the header of a slice.

According to an embodiment, identifier values for pictures are encoded according to a numbering scheme, and the identifier value for the indicated first picture of an independent sequence is reset, preferably to zero.

According to an embodiment, an identifier value for the independent sequence is encoded into the video sequence.

An advantage of the procedure of the invention is that it enables to start browsing a video sequence from a random point, i.e. it provides the decoder with the information about the first picture of an independently decodable sequence. Thus, the decoder knows that by decoding this first picture, it is possible to continue the decoding process without any prediction from any prior picture. Accordingly, a further advantage is that the decoder may discard any picture decoded prior to said initiation picture from its buffer memory, since the prior pictures are no longer needed in the decoding process. A further advantage is that the procedure of the invention allows a separate video sequence to the easily inserted into another video sequence.

A further advantage is that enables identification of a picture boundary between two back-to-back initiation pictures by looking at the sub-sequence number of the initiation pictures. A yet further advantage relates to detection of losses of image frames that start an independently decodable sub-sequence. If such an image frame is lost e.g. during transmission, it is unlikely that any error concealment method would result into a subjectively satisfactory image quality. It is therefore an advantage that decoders are provided means to detect losses of image frames that start an independently decodable sub-sequence. Decoders may react to such a loss by requesting a retransmission or picture refresh, for example.

BRIEF DESCRIPTION OF THE DRAWINGS

In the following, the invention will be described in connection with the preferred embodiments and with reference to the accompanying drawings, in which

FIG. 1 illustrates a common multimedia data streaming system in which the scalable coding hierarchy of the invention can be applied;

FIG. 2 illustrates a scalable coding hierarchy of a preferred embodiment of the invention;

FIGS. 3 a and 3 b illustrate embodiments of the invention for adjusting scalability;

FIGS. 4 a, 4 b and 4 c illustrate embodiments of the invention for adjusting image numbering;

FIGS. 5 a, 5 b and 5 c illustrate embodiments of the invention for using B-frames in a scalable coding hierarchy;

FIGS. 6 a, 6 b and 6 c illustrate scalable coding hierarchies of preferred embodiments of the invention in connection with reference picture selection; and

FIG. 7 illustrates an arrangement according to a preferred embodiment of the invention for coding scene transition.

DETAILED DESCRIPTION OF THE INVENTION

In the following, a general-purpose multimedia data streaming system is disclosed, the basic principles of which can be applied in connection with any telecommunications system. Although the invention is described here with a particular reference to a streaming system, in which the multimedia data is transmitted most preferably through a telecommunications network employing a packet-switched data protocol, such as an IP network, the invention can equally well be implemented in circuit-switched networks, such as fixed telephone networks PSTN/ISDN (Public Switched Telephone Network/integrated Services Digital Network) or in mobile communications networks PLMN (Public Land Mobile Network). Further, the invention can be applied in the streaming of multimedia files in the form of both normal streaming and progressive downloading, and for implementing video calls, for example.

It is also to be noted that although the invention is described here with a particular reference to streaming systems and the invention can also be advantageously applied in them, the invention is not restricted to streaming systems alone, but can be applied in any video reproduction system, irrespective of how a video file that is to be decoded is downloaded and where it is downloaded from. The invention can therefore be applied for example in the playback of a video file to be downloaded from a DVD disc or from some other computer memory carrier, for example in connection with varying processing capacity available for video playback. In particular, the invention can be applied to different video codings of low bit rate that are typically used in telecommunications systems subject to bandwidth restrictions. One example is the system defined in the ITU-T standard H.263 and the one that is being defined in H.26L (possibly later to become H.264). In connection with these, the invention can be applied to mobile stations, for example, in which case the video playback can be made to adjust both to changing transfer capacity or channel quality and to the processor power currently available, when the mobile station is used also for executing other applications than video playback.

It is further to be noted that, for the sake of clarity, the invention will be described below by giving an account of image frame coding and temporal predicting on image frame level. However, in practice coding and temporal predicting typically take place on block or macroblock level, as described above.

With reference to FIG. 1, a typical multimedia streaming system will be described, which is a preferred system for applying the procedure of the invention.

A multimedia data streaming system typically comprises one or more multimedia sources 100, such as a video camera and a microphone, or video image or computer graphic files stored in a memory carrier. Raw data obtained from the different multimedia sources 100 is combined into a multimedia file in an encoder 102, which can also be referred to as an editing unit. The raw data arriving from the one or more multimedia sources 100 is first captured using capturing means 104 included in the encoder 102, which capturing means can be typically implemented as different interface cards, driver software, or application software controlling the function of a card. For example, video data may be captured using a video capture card and the associated software. The output of the capturing means 104 is typically either an uncompressed or slightly compressed data flow, for example uncompressed video frames of the YUV 4:2:0 format or motion-JPEG image format, when a video capture card is concerned.

An editor 106 links different media flows together to synchronize video and audio flows to be reproduced simultaneously as desired. The editor 106 may also edit each media flow, such as a video flow, by halving the frame rate or by reducing spatial resolution, for example. The separate, although synchronized, media flows are compressed in a compressor 108, where each media flow is separately compressed using a compressor suitable for the media flow. For example, video frames of the YUV 4:2:0 format may be compressed using the low bit rate video coding according to the ITU-T recommendation H.263 or H.26L. The separate, synchronized and compressed media flows are typically interleaved in a multiplexer 110, the output obtained from the encoder 102 being a single, uniform bit flow that comprises data of a plural number of media flows and that may be referred to as a multimedia file. It is to be noted that the forming of a multimedia file does not necessarily require the multiplexing of a plural number of media flows into a single file, but the streaming server may interleave the media flows just before transmitting them.

The multimedia files are transferred to a streaming server 112, which is thus capable of carrying out the streaming either as real-time streaming or in the form of progressive downloading. In progressive downloading the multimedia files are first stored in the memory of the server 112 from where they may be retrieved for transmission as need arises. In real-time streaming the editor 102 transmits a continuous media flow of multimedia files to the streaming server 112, and the server 112 forwards the flow directly to a client 114. As a further option, real-time streaming may also be carried out such that the multimedia files are stored in a storage that is accessible from the server 112, from where real-time streaming can be driven and a continuous media flow of multimedia files is started as need arises. In such case, the editor 102 does not necessarily control the streaming by any means. The streaming server 112 carries out traffic shaping of the multimedia data as regards the bandwidth available or the maximum decoding and playback rate of the client 114, the streaming server being able to adjust the bit rate of the media flow for example by leaving out B-frames from the transmission or by adjusting the number of the scalability layers. Further, the streaming server 112 may modify the header fields of a multiplexed media flow to reduce their size and encapsulate the multimedia data into data packets that are suitable for transmission in the telecommunications network employed. The client 114 may typically adjust, at least to some extent, the operation of the server 112 by using a suitable control protocol. The client 114 is capable of controlling the server 112 at least in such a way that a desired multimedia file can be selected for transmission to the client, in addition to which the client is typically capable of stopping and interrupting the transmission of a multimedia file.

When the client 114 is receiving a multimedia file, the file is first supplied to a demultiplexer 116, which separates the media flows comprised by the multimedia file. The separate, compressed media flows are then supplied to a decompressor 118 where each separate media flow is decompressed by a decompressor suitable for each particular media flow. The decompressed and reconstructed media flows are supplied to a playback unit 120 where the media flows are rendered at a correct pace according to their synchronization data and supplied to presentation means 124. The actual presentation means 124 may comprise for example a computer or mobile station display, and loudspeaker means. The client 114 also typically comprises a control unit 122 that the end user can typically control through a user interface and that controls both the operation of the server, through the above-described control protocol, and the operation of the playback unit 120, on the basis of the instructions given by the end user.

It is to be noted that the transfer of multimedia files from the streaming server 112 to the client 114 takes place through a telecommunications network, the transfer path typically comprising a plural number of telecommunications network elements. It is therefore possible that there is at least some network element that can carry out traffic shaping of multimedia data with regard to the available bandwidth or the maximum decoding and playback rate of the client 114 at least partly in the same way as described above in connection with the streaming server.

Scalable coding will be described below with reference to a preferred embodiment of the invention and an example illustrated in FIG. 2. FIG. 2 shows part of a compressed video sequence having a first frame 200, which is an INTRA frame, or I-frame, and thus an independently determined video frame the image information of which is determined without using motion-compensated temporal prediction. The I-frame 200 is placed on a first scalability layer, which may be referred to as an INTRA layer. Each scalability layer is assigned a unique identifier, such as the layer number. The INTRA layer may therefore be given the number 0, for example, or some other alphanumeric identifier, for example a letter, or a combination of a letter and a number.

Correspondingly, sub-sequences consisting of groups of one or more video frames are determined for each scalability layer, at least one of the images in a group (typically the first or the last one) being temporally predicted at least from a video frame of another, sub-sequence of typically either a higher or the same scalability layer, the rest of the video frames being temporally predicted either from only the video frames of the same sub-sequence, or possibly also from one or more video frames of said second sub-sequence. A sub-sequence may de decoded independently, irrespective of other sub-sequences, except said second sub-sequence. The sub-sequences of each scalability layer are assigned a unique identifier using for example consecutive numbering starting with number 0 given for the first sub-sequence of a scalability layer. Since the I-frame 200 is determined independently and can also be decoded independently upon reception, irrespective of other image frames, it also forms in a way a separate sub-sequence.

An essential aspect of the present invention is therefore to determine each sub-sequence in terms of those sub-sequences the sub-sequence is dependent on. In other words, a sub-sequence comprises information about all the sub-sequences that have been directly used for predicting the image frames of the sub-sequence in question. This information is signalled in a video sequence bit stream, preferably separate from the actual image information, and therefore the image data of the video sequence can be preferably adjusted because it is easy to determine video sequence portions that are to be independently decoded and can be removed without affecting the decoding of the rest of the image data.

Next, within each sub-sequence, the video frames of the sub-sequence are given image numbers, using for example consecutive numbering that starts with the number 0 given to the first video frame of the sub-sequence. Since the I-frame 200 also forms a separate sub-sequence, its image number is 0. In FIG. 2, the I-frame 200 shows the type (I), sub-sequence identifier and image number (0.0) of the frame.

FIG. 2 further shows a next I-frame 202 of the INTRA layer, the frame thus being also an independently determined video frame that has been determined without using motion-compensated temporal prediction. The temporal transmission frequency of I-frames depends on many factors relating to video coding, image information contents and the bandwidth to be used, and, depending on the application or application environment, I-frames are transmitted in a video sequence at intervals of 0.5 to 10 seconds, for example. Since the I-frame 202 can be independently decoded, it also forms a separate sub-sequence. Since this is the second sub-sequence in the INTRA-layer, the consecutive numbering of the sub-sequence identifier of the I-frame 202 is 1. Further, since the I-frame 202 also forms a separate sub-sequence, i.e. it is the only video frame in the sub-sequence, its image number is 0. The I-frame 202 can thus be designated with identifier (I.1.0.) Correspondingly, the identifier of the next I-frame on the INTRA layer is (I.2.0.), etc. As a result, only independently determined I-frames in which the image information is not determined using motion-compensated temporal prediction are coded into the first scalability layer, i.e. the INTRA layer. The sub-sequences can also be determined using other kind of numbering or other identifiers, provided that the sub-sequences can be distinguished from one another.

The next scalability layer, which has a layer number 1, for example, and which may be referred to as the base layer, comprises coded, motion-compensated INTER or P-frames typically predicted only from previous image frames, i.e. in this case from the I-frames of an upper INTRA layer. The image information of the first P-frame 204 of the base layer shown in FIG. 2 is determined using the I-frame 200 of the INTRA layer. A P-frame 204 begins the first sub-sequence of the base layer, and therefore the sub-sequence identifier of the P-frame 204 is 0. Further, since the P-frame 204 is the first image frame of the first sub-sequence of the base layer, the image number of the P-frame 204 is 0. The P-frame 204 can thus be identified with (P.0.0).

The temporally succeeding P-frame 206 of the base layer is predicted from the previous P-frame 204. The P-frames 204 and 206 thus belong to the same sub-sequence, whereby the P-frame 206 also receives the sub-sequence identifier 0. Since the P-frame 206 is the second image frame in the sub-sequence 0, the image number of the P-frame 206 is 1, and the P-frame 206 can be identified with (P.0.1).

The scalability layer succeeding the base layer and having the layer number 2, is called enhancement layer 1. This layer comprises coded, motion-compensated P-frames predicted only from previous image frames, in this case either from I-frames of the INTRA layer or P-frames of the base layer. FIG. 2 shows a first image frame 208 and a second image frame 210 of enhancement layer 1, which are both predicted only from the first image frame 200 of the INTRA layer. The P-frame 208 begins the first sub-sequence of enhancement layer 1, the sub-sequence identifier of the P-frame thus being 0. Further, since the P-frame 208 is the first and only image frame in said sub-sequence, the P-frame 208 receives the image number 0. The P-frame 208 can thus be identified with (P.0.0.).

Since the second image frame 210 is also predicted only from the first image frame 200 of the INTRA layer, the P-frame 210 begins the second sub-sequence of enhancement layer 1 and the sub-sequence identifier of the P-frame 210 is therefore 1. Since the P-frame 210 is the first image frame in the sub-sequence, the image number of the P-frame 210 is 0. The P-frame can thus be identified with (P.1.0.). The temporally succeeding P-frame 212 of enhancement layer 1 is predicted from the previous P-frame 210. The P-frames 210 and 212 thus belong to the same sub-sequence, and therefore the P-frame also receives the sub-sequence identifier 1. The P-frame 212 is the second image frame in the sub-sequence 1, and therefore the P-frame receives the image number 1 and can be identified with (P.1.1).

The temporally fourth image frame 214 of enhancement layer 1 is predicted from the first image frame 204 of the base layer. The P-frame 214 thus begins a third sub-sequence of enhancement layer 1 and therefore the P-frame 214 receives the sub-sequence identifier 2. Further, since the P-frame 214 is the first and only image frame in the sub-sequence, the image number of the P-frame 214 is 0. The P-frame 208 can therefore be identified with (P.2.0).

Also the temporally fifth image frame 216 of enhancement layer 1 is predicted only from the first image frame 204 of the base layer, the P-frame 216 thus beginning the fourth sub-sequence of enhancement layer 1, and the sub-sequence identifier of the P-frame 216 is 3. In addition, since the P-frame 216 is the first one in the sub-sequence in question, the image number of the P-frame 216 is 0. The P-frame 216 can therefore be identified with (P.3.0). The temporally following P-frame 218 of enhancement layer 1 is predicted from the previous P-frame 216. The P-frames 216 and 218 thus belong to the same sub-sequence, and the sub-sequence identifier of the P-frame 218 is also 3. Since the P-frame 218 is the second image frame in the sub-sequence 3, the image number of the P-frame 218 is 1 and the identifier of the P-frame 218 is (P.3.1).

For simplicity and clarity of illustration the above disclosure only relates to I- and P-frames. However, a person skilled in the art will find it apparent that the scalable video coding of the invention can also be implemented using other known image frame types, such as the above described B-frames and at least SI-frames, SP-frames and MH-frames. SI-frames correspond to I-frames, but together with an SP-frame they allow an identical image to be reconstructed. An SP-frame, in turn, is a P-frame subjected to a particular coding that allows an identical image to be reconstructed together with an SI-frame or another SP-frame. SP-frames are typically placed into a video sequence into points where an access point or a scanning point is desired, or where the changing of the coding parameters of the video stream should be possible. The frames can also be used for error correction and for increasing error tolerance. SP-frames are otherwise similar to ordinary P-frames predicted from previous frames, except that they are defined so that they can be replaced by another video frame of the SP- or SI-type, the result of the decoding of the new frame being identical with the decoding result of the original SP-frame that was in the video stream. In other words, a new SP-frame that is used for replacing the one that was in the video stream is predicted from another sequence or video stream and yet the reconstructed frame has identical contents. SP-frames are described for example in the Applicant's earlier application PCT/FI02/00004.

Similarly as B-frames, macroblocks of MH (Multi Hypothesis) frames, based on motion-compensated prediction, are predicted from two other frames, which are not, however, necessarily located next to an MH-frame. More precisely, the predicted macroblocks are computed as an average of two macroblocks of two other frames. Instead of two frames, MH-frame macroblocks can naturally be also predicted from one other frame. Reference images may change according to macroblock, in other words, all macroblocks in one and the same image are not necessarily predicted using the same frames.

A sub-sequence thus covers a specific period of time in a video sequence. The sub-sequences of the same layer or of different layers may be partly or entirely overlapping. If there are temporally overlapping image frames on the same layer, the frames are interpreted as alternative presentations of the same image content and therefore any mode of image presentation can be used. On the other hand, if there are temporally overlapping image frames on different layers, they form different presentations of the same image content, and therefore presentations differ in image quality, i.e. the quality of image is better on a lower layer.

The above disclosure referring to FIG. 2 illustrates a scalable coding arrangement and a hierarchical structure and numbering of image frames according to a preferred embodiment of the invention. In this embodiment the INTRA-layer only comprises I-frames and the base layer can only be decoded using the information received from the INTRA-layer. Correspondingly, the decoding of enhancement layer 1 typically requires information from both the base layer and the INTRA-layer.

The number of the scalability layers is not restricted to three, as above, but any number of enhancement layers that is considered necessary for producing sufficient scalability may be used. Consequently, the layer number of enhancement layer 2 is four, that of enhancement layer 3 is five, etc. Since some of the image frames in the above example are given the same identifier (e.g. the identifier of both image frames 204 and 208 is (P.0.0)), by including the layer number in the identifier each image frame can be uniquely identified and, at the same time, the dependencies of each image frame on other image frames is preferably determined. Each image frame is thus uniquely identified, the identifier of image frame 204, for example, being (P.1.0.0), or simply (1.0.0) and, correspondingly, that of image 208 being (P.2.0.0), or (2.0.0).

According to a preferred embodiment of the invention, the number of a reference image frame is determined according to a specific, pre-determined alpha-numeric series, for example as an integer between 0 and 255. When the parameter value achieves the maximum value N (e.g. 255) in the series concerned, the determining of the parameter value starts from the beginning, i.e. from the minimum value of the series (e.g. 0). An image frame is thus uniquely identified within a specific sub-sequence up to the point where the same image number is used again. The sub-sequence identifier can also be determined according to a specific, predetermined arithmetic series. When the value of the sub-sequence identifier achieves the maximum value N of the series, the determining of the identifier starts again from the beginning of the series. However, a sub-sequence cannot be assigned an identifier that is still in use (within the same layer). The series in use may also be determined in another way than arithmetically. One alternative is to assign random sub-sequence identifiers, taking into account that an assigned identifier is not be used again.

A problem in the numbering of image frames arises when the user wishes to start browsing a video file in the middle of a video sequence. Such situations occur for example when the user wishes to browse a locally stored video file backward or forward or to browse a streaming file at a particular point; when the user initiates the playback of a streaming file from a random point; or when a video file that is to be reproduced is detected to contain an error that interrupts the playback or requires the playback to be resumed from a point following the error. When the browsing of a video file is resumed from a random point after previous browsing, discontinuity typically occurs in the image numbering. The decoder typically interprets this as unintentional loss of image frames and unnecessarily tries to reconstruct the image frames suspected as lost.

According to a preferred embodiment of the invention, this can be avoided in the decoder by defining an initiation image in an independently decodable Group of Pictures GOP that is activated at the random point of the video file, and the number of the initiation image is set at zero. This independently decodable image group can thus be a sub-sequence of an INTRA-layer, for example, in which case an I-frame is used as the initiation image, or, if scaling originating from the base layer is employed, the independently decodable image group is a sub-sequence of the base layer, in which case the first image frame of the sub-sequence, typically an I-frame, is usually used as the initiation image. Consequently, when activated at a random point, the decoder preferably sets the identifier of the first image frame, preferably an I-frame, of the independently decodable sub-sequence at zero. Since the sub-sequence to be decoded may also comprise other image frames whose identifier is zero (for example when the above described alpha-numeric series starts from the beginning), the beginning of the sub-sequence, i.e. its first image frame, can be indicated to the decoder for example by a separate flag added to the header field of a slice of the image frame. This allows the decoder to interpret the image numbers correctly and to find the correct image frame that initiates the sub-sequence from the video sequence image frames.

The above numbering system provides only one example of how the unique image frame identification of the invention can be carried out so that interdependencies between the image frames are indicated at the same time. However, video coding methods in which the method of the invention can be applied, such as video coding methods according to the ITU-T standards H.263 and H.26L, employ code tables, which in turn use variable length codes. When variable length codes are used for coding layer numbers, for example, a lower code word index, i.e. a smaller layer number, signifies a shorter code word. In practice the scalable coding of the invention will be used in most cases in such a way that the base layer will consist significantly more image frames than the INTRA-layer. This justifies the use of a lower index, i.e. a smaller layer number, on the base layer than on the INTRA-layer, because the amount of coded video data is thereby advantageously reduced. Consequently, the INTRA-layer is preferably assigned layer number 1 and the base layer is given layer number 0. Alternatively, the code can be formed by using fewer bits for coding the base layer number than the INTRA-layer number, in which case the actual layer number value is not relevant in view of the length of the code created.

Further, according to a second preferred embodiment of the invention, when the number of the scalability layers is to be kept low, the first scalability layer in particular can be coded to comprise both the INTRA-layer and the base layer. From the point of view of coding hierarchy, the simplest way to conceive this is to leave out the INTRA-layer altogether, and to provide the base layer with coded frames consisting of both independently defined I-frames, the image information of which has not been determined using motion-compensated temporal prediction, and image frames predicted from previous frames, which image frames in this case are motion-compensated P-frames predicted from the I-frames of the same layer. The layer number 0 can thus still be used for the base layer and, if enhancement layers are coded into the video sequence, enhancement layer 1 is assigned layer number 1. This is illustrated in the following, with reference to FIGS. 3 a and 3 b.

FIG. 3 a shows a non-scalable video sequence structure, in which all image frames are placed on the same scalability layer, i.e. the base layer. The video sequence comprises a first image frame 300 which is an I-frame (I.0.0) and which thus initiates a first sub-sequence. The image frame 300 is used for predicting a second image frame 302 of the sub-sequence, i.e. a P-frame (P.0.1), which is then used for predicting a third image frame 304 of the sub-sequence, i.e. a P-frame (P.0.2), which is in turn used for predicting the next image frame 306, i.e. a P-frame (P.0.3). The video sequence is then provided with an I-frame (I.1.0) coded therein, i.e. an I-frame 308, which thus initiates a second sub-sequence in the video sequence. This kind of non-scalable coding can be used for example when the application employed does not allow scalable coding to be used, or there is no need for it. In a circuit-switched videophone application, for example, channel bandwidth remains constant and the video sequence is coded in real-time, and therefore there is typically no need for scalable coding.

FIG. 3 b, in turn, illustrates an example of how scalability can be added, when necessary, to a combined INTRA- and base layer. Here, too, the video sequence base layer comprises a first image frame 310 which is an I-frame (I.0.0) and which initiates a first sub-sequence of the base layer. The image frame 310 is used for predicting a second image frame 312 of the sub-sequence, i.e. a P-frame (P.0.1), which is then used for predicting a third image frame 314 of the sub-sequence, i.e. a P-frame (P.0.2). Enhancement layer 1, however, is also coded into this video sequence and it comprises a first sub-sequence, the first and only image frame 316 of which is a P-frame (P.0.0), which is predicted from the first image frame 310 of the base layer. The first image frame 318 of a second sub-sequence of the enhancement layer is, in turn, predicted from the second image frame 312 of the base layer, and therefore the identifier of this P-frame is (P.1.0). The next image frame 320 of the enhancement layer is again predicted from the previous image frame 318 of the same layer and, therefore, it belongs to the same sub-sequence, its identifier thus being (P.1.1).

In this embodiment of the invention the sub-sequences of the base layer can be decoded independently, although a base layer sub-sequence may be dependent on another base layer sub-sequence. The decoding of the base layer sub-sequences requires information from the base layer and/or from the second sub-sequence of enhancement layer 1, the decoding of the sub-sequences of enhancement layer 2 requires information from enhancement layer 1 and/or from the second sub-sequence of enhancement layer 2, etc. According to an embodiment, I-frames are not restricted to the base layer alone, but lower enhancement layers may also comprise I-frames.

The basic idea behind the above embodiments is that a sub-sequence comprises information about all the sub-sequences it is dependent on, i.e. about all sub-sequences that have been used for predicting at least one of the image frames of the sub-sequence in question. However, according to an embodiment it is also possible that a sub-sequence comprises information about all sub-sequences that are dependent on the sub-sequence in question, in other words, about all the sub-sequences in which at least one image frame has been predicted using at least one image frame of the sub-sequence in question. Since in the latter case the dependencies are typically determined temporally forward, image frame buffers can be advantageously utilized in the coding in a manner to be described later.

In all the above embodiments the numbering of the image frames is sub-sequence-specific, i.e. a new sub-sequence always starts the numbering from the beginning. The identification of an individual image frame thus requires the layer number, sub-sequence identifier and image frame number to be determined. According to a preferred embodiment of the invention, the image frames can be independently numbered using consecutive numbering in which successive reference image frames in the coding order are indicated with numbers incremented by one. As regards layer numbers and sub-sequence identifiers, the above-described numbering procedure can be used. This allows each image frame to be uniquely identified, when necessary, without using the layer number and sub-sequence identifier.

This is illustrated with the example shown in FIG. 4 a in which the base layer comprises a temporally first I-frame 400 (I.0.0). This frame is used for predicting a first image frame 402 of enhancement layer 1, i.e. (P.0.1), which is then used for predicting a second image frame 404 belonging to the same sub-sequence (with sub-sequence identifier 0), i.e. (P.0.2), which is used for predicting a third image frame 406 of the same sub-sequence, i.e. (P.0.3), which is used for predicting a fourth image frame 408 (P.0.4) and, finally, the fourth frame for predicting a fifth image frame 410 (P.0.5). The temporally next video sequence image frame 412 is located on the base layer, where it is in the same sub-sequence as the I-frame 400, although temporally it is only the seventh coded image frame, and therefore its identifier is (P.0.6). The seventh frame is then used for predicting a first image frame 414 of the second sub-sequence of enhancement layer 1, i.e. (P.1.7), which is then used for predicting a second image frame 416 belonging to the same sub-sequence (with sub-sequence identifier 1), i.e. (P.1.8), which in turn used for predicting a third image frame 418 (P.1.9), the third for predicting a fourth image frame 420 (P.1.10) and, finally, the fourth for predicting a fifth image frame 422 (P.1.11) of the same sub-sequence. Again, the temporally next video sequence image frame 424 is located on the base layer, where it is in the same sub-sequence as the I-frame 400 and the P-frame 412, although temporally it is only the thirteenth coded image frame and therefore its identifier is (P.0.12). For clarity of illustration, the above description of the embodiment does not comprise layer identifiers, but it is apparent that in order to implement scalability, also the layer identifier must be signalled together with the video sequence, typically as part of the image frame identifiers.

FIGS. 4 b and 4 c show alternative embodiments for grouping the image frames of the video sequence shown in FIG. 4 a. The image frames in FIG. 4 b are numbered according to sub-sequence, i.e. a new sub-sequence always starts the numbering from the beginning (from zero). FIG. 4 c, in turn, employs image frame numbering which corresponds otherwise to that used in FIG. 4 a, except that the P-frames of the base layer are replaced by SP-frame pairs to allow for identical reconstruction of image information.

As stated above, the procedure of the invention can also be implemented using B-frames. One example of this is illustrated in FIGS. 5 a, 5 b and 5 c. FIG. 5 a shows a video sequence in the time domain, the sequence comprising P-frames P1, P4 and P7, with B-frames placed between them, the interdependencies of the B-frames with regard to temporal predicting being shown with arrows. FIG. 5 b shows a preferred grouping of video sequence image frames in which the interdependencies shown in FIG. 5 a are indicated. FIG. 5 b illustrates sub-sequence-specific image frame numbering in which a new sub-sequence always starts the numbering of the image frames from zero. FIG. 5 c, in turn, illustrates image frame numbering, which is consecutive in the order of temporal prediction, wherein the following reference frame always receives the next image number as the previously encoded reference frame. The image frame (B1.8) (and (B2.10)) does not serve as a reference prediction frame to any other frame, therefore it does not affect the image frame numbering.

The above examples illustrate different alternatives of how scalability of video sequence coding can be adjusted by using the method of the invention. From the point of view of the terminal device reproducing the video sequence, the more scalability layers are available, or the more scalability layers it is capable of decoding, the better the image quality. In other words, increase in the amount of image information and in the bit rate used for transferring the information improves the temporal or spatial resolution, or the spatial quality of the image data. Correspondingly, a higher number of scalability layers also sets considerably higher demands on the processing capacity of the terminal device performing decoding.

In addition, the above examples illustrate the advantage gained by using sub-sequences. With image frame identifiers, the dependencies of each image frame from other image frames in the sub-sequence are indicated in an unambiguous manner. A sub-sequence thus forms an independent whole that can be left out of a video sequence, when necessary, without affecting the decoding of subsequent image frames of the video sequence. In that case, only the image frames of the sub-sequence in question and of those sub-sequences on the same and/or lower scalability layers dependent on it are not decoded.

The image frame identifier data transmitted together with the video sequence are preferably included in the video sequence header fields or in the header fields of the transfer protocol to be used for transferring the video sequence. In other words, the identifier data of predicted image frames are not included in the image data of the coded video sequence, but always into the header fields, whereby the dependencies of the image frames can be detected without decoding the images of the actual video sequence. The identifier data of the image frames can be stored for example in the buffer memory of the streaming server as the video sequence is being coded for transmission. In addition, the sub-sequences can be independently decoded on each scalability layer, because the image frames of a sub-sequence are not dependent on other sub-sequences of the same scalability layer.

According to an embodiment of the invention, the image frames comprised by a sub-sequence may thus depend also on other sub-sequences of the same scalability layer. This dependency must then be signalled for example to the streaming server carrying out traffic shaping, because interdependent sub-sequences located on the same layer cannot be separately removed from a video sequence to be transmitted. A preferred way to carry out the signalling is to include it in the image frame identifiers to be transmitted, for example by listing the layer-sub-sequence pairs the sub-sequence in question depends on. This also provides a preferred way of indicating dependency from another sub-sequence of the same scalability layer.

The above examples illustrate a situation where image frames are temporally predicted from previous image frames. In some coding methods, however, the reference picture selection has been further extended to also include the predicting of the image information of image frames from temporally succeeding image frames. Reference picture selection offers most diversified means for creating different temporally scalable image frame structures and allows the error sensitivity of the video sequence to be reduced. One of the coding techniques based on reference picture selection is INTRA-frame postponement. The INTRA-frame is not placed into its temporally “correct” position in the video sequence, but its position is temporally postponed. The video sequence image frames that are between the “correct” position of the INTRA-frame and its actual position are predicted temporally backward from the INTRA-frame in question. This naturally requires that uncoded image frames be buffered for a sufficiently long period of time so that all image frames that are to be displayed can be coded and arranged into their order of presentation. INTRA-frame transfer and the associated determining of sub-sequences in accordance with the invention are illustrated in the following with reference to FIG. 6.

FIG. 6 a shows a video sequence part in which the INTRA-frame comprises a single I-frame 600, which is temporally transferred to the position shown in FIG. 6, although the “correct” position of the I-frame in the video sequence would have been at the first image frame. The video sequence image frames between the “correct” position and the real position 600 are thus temporally predicted backward from the I-frame 600. This is illustrated by a sub-sequence coded into enhancement layer 1 and having a first temporally backward predicted image frame 602, which is a P-frame (P.0.0). This frame is used for temporally predicting a previous image frame 604, i.e. a P-frame (P.0.1), which is used in turn for predicting an image frame 606, i.e. a P-frame (P.0.2), and, finally, the frame 606 for predicting an image frame 608, i.e. a P-frame (P.0.3), which is at the position that would have been the “correct” position of the I-frame 600 in the video sequence. Correspondingly, the I-frame 600 on the base layer is used for temporally forward prediction of a sub-sequence comprising four P-frames 610, 612, 614 and 616, i.e. P-frames (P.0.0), (P.0.1), (P.0.2) and (P.0.3).

The fact that in this example backward predicted image frames are placed on a lower layer than forward predicted image layers indicates that for purposes of illustration, backward predicted image frames are in this coding example considered subjectively less valuable than forward predicted image frames. Naturally the sub-sequences could both be placed on the same layer, in which case they would be considered equal, or a backward predicted sub-sequence could be on the upper layer, in which case it would be considered subjectively more valuable.

FIGS. 6 b and 6 c show some alternatives for coding a video sequence according to FIG. 6 a. In FIG. 6 b both forward and backward predicted sub-sequences are placed on the base layer, the I-frame being only located on the INTRA-layer. The forward predicted sub-sequence on this layer is thus the second sub-sequence and its sub-sequence identifier is 1. In FIG. 6 c, in turn, an I-frame and a forward predicted sub-sequence based on it are located on the base layer, while a backward predicted sub-sequence is located on enhancement layer 1.

Moreover, according to a preferred embodiment of the invention, the above-described scalability can be utilized for coding what is known as a scene transition into a video sequence. Video material, such as news reports, music videos and movie trailers, often comprise rapid cuts between separate image material scenes. Sometimes the cuts are abrupt, but often a procedure known as scene transition is used in which transfer from one scene to another takes place by dimming, wiping, mosaic dissolving or scrolling the image frames of a previous scene, and, correspondingly, by presenting those of a later scene. From the point of view of coding efficiency, the video coding of a scene transition is often most problematic, because the image frames appearing during the scene transition comprise information on the image frames of both the terminating and the initiating scene.

A typical scene transition, fading, is carried out by gradually reducing the intensity or luminance of the image frames of a first scene to zero, while gradually increasing the intensity of the image frames of a second scene to its maximum value. This scene transition is referred to as cross-faded scene transition.

Generally speaking, a computer-made image can be thought of as consisting of layers, or image objects. Each object can be defined with reference to at least three information types: the structure of the image object, its shape and transparency, and the layering order (depth) in relation to the background of the image and to other image objects. Shape and transparency are often determined using what is known as an alpha plane, which measures opacity and the value of which is usually determined separately for each image object, possibly excluding the background, which is usually determined as non-transparent. The alpha plane value of a non-transparent image object, such as the background, can thus be set at 1.0, whereas the alpha plane value of a fully transparent image object is 0.0. The values in between define the intensity of the visibility of a specific image object in a picture in proportion to the background and to other, at least partly overlapping, image objects that have a higher depth value than the image object in question.

The superimposition of image objects in layers according to their shape, transparency and depth position is referred to as scene composition. In practice the procedure is based on the use of weighted averages. First, the image object that is closest to the background, i.e. deepest according to its depth position, is placed onto the background and a combined image is formed of the two. The pixel values of the combined image are formed as an average weighted by the alpha plane values of the background image and the image object in question. The alpha plane value of the combined image is then set at 1.0, after which it serves as a background image for the next image object. The process continues until all image objects are attached to the image.

In the following, a procedure according to a preferred embodiment of the invention will be described in which video sequence scalability layers are combined with the above described image objects of image frames and their information types to provide a scene transition with scalable video coding that also has good compression efficiency.

This embodiment of the invention is illustrated in the following by way of example and in a simplified manner by using cross-faded scene transition, on one hand, and abrupt scene transition, on the other hand, as examples. The image frames to be displayed during a scene transition are typically formed of two superimposed image frames, a first image frame comprising a first image scene and a second image frame a second scene. One of the image frames serves as the background image and other, which is referred to as a foreground image, is placed on top of the background image. The opacity of the background image, i.e. its non-transparency value, is constant. In other words, its pixel-specific alpha plane values are not adjusted.

In this embodiment of the invention, the background and foreground images are both defined according to scalability layer. This is illustrated in FIG. 7, which shows an example of how image frames of two different scenes can be placed on scalability layers during a scene transition of the invention. FIG. 7 shows a first image frame 700 of a first (terminating) scene positioned on the base layer. The image frame 700 may be either an I-frame containing image information that has not been determined using motion-compensated temporal predicting, or it may be a P-frame that is a motion-compensated image frame predicted from previous image frames. The coding of a second (initiating) scene starts during the temporally following image frame and, according to the invention, the image frames of the scene are also placed on the base layer. Remaining image frames 702, 704 of the second (terminating) scene are then placed on enhancement layer 1. These image frames are typically P-frames.

In this embodiment, the image frames of the second (initiating) scene are thus placed on the base layer, at least for the duration of the scene transition. The first image frame 706 of the scene is typically an I-frame, and it is used for temporally predicting the succeeding image frames of the scene. Consequently, the succeeding image frames of the second scene are temporally predicted frames, typically P-frames, such as frames 708 and 710 shown in FIG. 7.

According to a preferred embodiment of the invention, this placing of image frames on scalability layers can be used for implementing a cross-faded scene transition by determining the image layer that is on the base layer always as a background image of maximum opacity (100%), or non-transparency value. During a scene transition, image frames located on enhancement layers are placed onto the background image and their opacity is adjusted for example by means of suitable filters such that the frames gradually change from non-transparent to transparent.

In the video sequence of FIG. 7, there are no image frames on the lower scalability layers during the first base layer image frame 700. For this time instant, the first image frame 700 is only coded into the video sequence.

The next image frame 706 of the base layer initiates a new (second) scene, during which the image frame 706 is provided with depth positioning that places it as the background image, and its opacity value is set to the maximum. Temporally simultaneously with the image frame 706 of the base layer, there is an image frame 702 of a terminating (first) scene on enhancement layer 1. To allow a cross-faded scene transition to be produced, the transparency of the frame 702 must be increased. The example of FIG. 7 assumes that the opacity of the image frame 702 is set at 67% and, in addition, the image frame 702 is provided with depth positioning that determines it as a foreground image. For this time instant, an image combining the image frames 706 and 702 is coded into the video sequence, image 706 being visible as a weaker image on the background and image 702 as a stronger image at the front, because its opacity value is essentially high (67%).

During the temporally following image frame, there is a second image frame 708 of the second scene on the base layer, the frame 708 being thus correspondingly provided with depth positioning determining it as a background image, and its opacity value is set to the maximum. Enhancement layer 1 further comprises the last image frame 704 of a temporally simultaneously terminating (first) scene, the opacity value of the frame being set at 33% and, in addition, the image frame 704 being provided with depth positioning that determines it as a foreground image as well. Consequently, for this time instant, an image combined of the image frames 708 and 704 is coded into the video sequence, the image 708 being displayed as a stronger image on the background and the image 704 as a weaker image on the foreground, because the opacity value of the image 704 is no longer more than 33%.

During the temporally following image frame, the base layer comprises a third image frame 710 of the second scene. Since the first scene has terminated, only the image frame 710 is coded into the video sequence, and the displaying of the second scene continues from the frame 710.

The above disclosure describes, by way of example, the positioning of image frames according to the invention on scalability layers to implement cross-faded scene transition in a manner that is advantageous from the point of view of coding efficiency. However, it is possible that when a video sequence is being transmitted or decoded, a situation arises in which the bit rate of the video sequence must be adjusted according to the maximum value of the bandwidth and/or terminal device decoding rate available for data transfer. This kind of bit rate control causes problems when the scene transition is to be implemented using prior art video coding methods.

A preferred embodiment of the present invention now allows one or more scalability layers, or independently decodable sub-sequences included in them, to be removed from a video sequence, whereby the bit rate of the video sequence can be decreased and yet, at the same time, the video sequence can be decoded without reducing image frequency. In the image frame positioning according to FIG. 7, this can be implemented by removing enhancement layer 1 from the video sequence. The video sequence is thus only used for displaying the image frames 700, 706, 708 and 710 of the base layer. In other words, a direct transition from the first (terminating) scene to the second (initiating) scene takes place in the form of an abrupt scene transition, i.e. directly from the image frame 700 of the first scene into the I-image frame 706 that initiates the second scene. The transition is thus not a cross-faded scene transition but an abrupt scene transition. Nevertheless, the scene transition can be carried out in an advantageous manner without affecting the quality of the video sequence image, and the viewer usually does not experience an abrupt scene transition carried out instead of a cross-faded scene transition in any way disturbing or faulty. On the contrary, since the prior art implementation does not allow scalability layers to be removed, scene transition would often require image frequency to be reduced, which the viewer would find jerky and disturbing.

The invention thus provides a preferred means for carrying out multimedia data traffic shaping in a streaming server comprising information about the different sub-sequences of a video sequence: their average bit rate, location in relation to the entire video sequence, duration and their interdependencies regarding the layers. The streaming server also determines the maximum value of the bandwidth available for the data transfer and/or the decoding rate of the terminal device. On the basis of this information, the streaming server decides how many scalability layers and which sub-sequences are transmitted in the video sequence. Bit rate control can thus be carried out, when necessary, by making first a rough adjustment of the number of the scalability layers, after which finer sub-sequence-specific adjustment can be easily carried out. At its simplest, bit rate control means making sub-sequence-specific decisions on whether a particular sub-sequence will be added to a video sequence or removed from it. In case of removal it is advisable to remove entire sub-sequences from a video sequence, because the removal of separate images may cause errors in other images of the same sub-sequence. For the same reason, all sub-sequences of a lower enhancement layer should be left out if they are dependent on the removed sub-sequence of a higher layer. If there are interdependent sub-sequences on one and the same scalability layer, sub-sequences dependent on an earlier sub-sequence must be removed if the earlier sub-sequence is removed.

If the image frame identifier data are added to a video sequence that is to be transmitted, traffic shaping can also be carried out in a telecommunications network element to be used for the transfer of the video sequence, for example in an Internet router, in different gateways, or at a base station or base station controller of a mobile communications network. For the network element to be able to maintain and process the sub-sequence information, it must have extra memory and processing capacity. For this reason traffic shaping that is to be carried out in the network is perhaps most probably executed using simple processing methods, such as the DiffServ, i.e. differentiated services, procedure that is supported by some IP-based networks. In the DiffServ method, each IP data packet is assigned a priority, whereby data packets of a higher priority are relayed faster and more reliably to the recipient than packets of a lower priority. This is advantageously applied to the scalability of the invention by determining not only scalability-layer-specific, but also sub-sequence-specific priorities, which enables a highly advanced priorisation.

There are many alternatives for adding image frame identifier data to a video sequence that is to be transmitted. In addition, it is also possible not to include any identifier data into the video sequence, in which case traffic shaping is only carried out at the streaming server. The identifier data can be included in the header fields of a video sequence, or in the header fields of the transfer protocol to be used, such as RTP (Real Time Protocol). According to a preferred embodiment, the identifier data can be transferred using a Supplemental Enhancement Information (SEI) mechanism. SEI provides a data delivery mechanism that is transferred synchronously with the video data content, thus assisting in the decoding and displaying of the video sequence. The SEI mechanism, particularly when used for transferring layer and sub-sequence information, is disclosed more in detail in the ITU-T standard document ITU-T Rec. H.264 (ISO/IEC 14496-10:2002), Annex D. In the cases, wherein a separate transfer protocol or mechanism is used for identifier data transfer, traffic shaping can be carried out also at one of the network elements of the transfer path. In addition, the receiving terminal device can control the decoding.

If the encoder or decoder supports reference picture selection, video sequence coding requires that decoded image frames be buffered before the coding so as to allow the relationships between different image frames to be temporally predicted from one or more other image frames. Image frame buffering can be arranged at least in two different ways, either as sliding windowing or as adaptive buffer memory control. In sliding windowing, M image frames that were coded last are used as a buffer. The frames in the buffer memory are in a decoded and reconstructed form, which allows them to be used as reference images in the coding. As the coding proceeds, the image frame buffering functions on the basis of the FIFO principle (First-In-First-Out). Images that are not used as reference images, such as conventional B-images, do not need to be stored in the buffer. Alternatively, the buffering can be also be implemented as adaptive buffer memory control, in which case the image buffering is not restricted to the FIFO principle, but image frames that are not needed can be removed from the buffer in the middle of the process, or, correspondingly, some image frames can be stored in the buffer for a longer period of time, if they are needed as reference images for later image frames. A known reference picture selection is implemented by indexing image frames that are in the buffer memory into a specific order, the image indices being then used to refer to an image in connection with motion-compensation, for example. This indexing method generally provides better compression efficiency compared to using image numbers, for example, for referring to a specific image when motion-compensation reference images are to be signalled.

The above reference image indexing method is sensitive to transfer errors, because the buffers of the sender's encoder and the recipient's decoder must contain mutually corresponding reconstructed images in identical order to ensure that the encoder and decoder both form the same indexing order. If the image frames are indexed in different order in the buffers of the encoder and the decoder, an incorrect reference image may be used in the decoder. To prevent this, it is essential that the decoder can be controlled to take into account image frames and sub-sequences that the encoder has intentionally removed from the video sequence. In that case the image frame numbering may comprise gaps, which the decoder typically interprets as errors and tries to reconstruct the image frames interpreted as lost. For this reason, it is essential that the encoder is capable to inform the decoder that the discontinuities in the image numbering of the transmitted image frames are intentional.

In response to this, and provided that sliding windowing is used for buffering the image frames, the decoder enters into the buffer memory a number of image frames, the contents of which may be fully random, corresponding to the missing image numbers. These random image frames are then designated by an identifier “invalid” to indicate that the frames in question do not belong to the actual video sequence, but are only filler frames entered for purposes of buffer memory management. A filler frame can naturally be implemented using only memory indicators, i.e. no data is preferably entered into the buffer memory, but memory management is used merely to store a reference to a generic “invalid” frame. The entering of the image frames of the actual video sequence continues from the correct image frame number after the number of filler frames indicated by the missing image numbers has been entered into the buffer, which allows the buffer memories of the encoder and the decoder to be kept preferably in synchronism. If during decoding a reference to an image number is detected which is then found to indicate a filler frame located in the buffer, error correction actions are initiated in the decoder to reconstruct the actual reference image, for example by asking the encoder to re-transmit the reference image in question.

Further, the procedure of the invention allows separate buffer memories to be used on the different scalability layers, or, correspondingly, sub-sequence-specifically. Each scalability layer may thus have a separate buffer memory that is conceptually separate and functions on the basis of the sliding window principle. Similarly, each sub-sequence may also be provided with a conceptually separate buffer memory that also functions on the basis of the sliding window principle. This means that the buffer memory is always emptied when a sub-sequence terminates. Separate buffer memories can be used in a preferred manner for reducing the need for signalling in certain situations in which ordinary sliding window buffering would be inadequate and actively adaptive buffer memory management would need to be used instead.

The H.26L standard defines a picture order count as a picture position in output order. The decoding process specified in the H.26L standard uses picture order counts to determine default index orderings for reference pictures in B slices, to represent picture order differences between frames and fields for vector scaling in motion vector prediction and for implicit mode weighted prediction in B slices, and to determine when successive slices in decoding order belong to different pictures. The picture order count is coded and transmitted for each picture.

In one embodiment of the invention, the decoder uses the picture order count to conclude that pictures are temporally overlapping, i.e., pictures that have an equal picture order count are temporally overlapping. Preferably, the decoder outputs only the picture on the highest received layer. In the absence of layer information, the decoder concludes that the latest temporally overlapping picture in decoding order resides on highest received layer.

The above disclosure describes a procedure for coding video frames for the purpose of producing a scalable, compressed video sequence. The actual procedure is carried out in a video encoder, such as the compressor 108 of FIG. 1, which may be any known video encoder. For example a video encoder according to the ITU-T recommendation H.263 or H.26L may be used, the video encoder being arranged to form, in accordance with the invention, a first sub-sequence into a video sequence, at least part of the sub-sequence being formed by coding I-frames; to form at least a second sub-sequence into the video sequence, at least part of the sub-sequence being formed by coding at least P- or B-frames, and at least one video frame of the second sub-sequence being predicted from at least one video frame of the first sub-sequence; and to determine into the video sequence the identification data of at least the video frames of the second sub-sequence.

According to the procedure of the invention, each sub-sequence of a particular scalability layer is preferably independently decodable, naturally taking into account dependencies from higher scalability layers and possibly other sub-sequences of the same scalability layer. A scalably compressed video sequence such as the one described above can thus be decoded by decoding a first sub-sequence of a video sequence, at least part of the sub-sequence having been formed by coding at least I-frames, and by decoding at least a second sub-sequence of the video sequence, at least part of the second sub-sequence having been formed by coding at least P- or B-frames, and at least one video frame of the second sub-sequence having been predicted from at least one video frame of the first sub-sequence, and by determining the identification and dependency data of at least the video frames comprised by the second sub-sequence of the video sequence, and by reconstructing at least part of the video sequence on the basis of the sub-sequence dependencies.

The actual decoding takes places in the video decoder, such as the decompressor 118 of FIG. 1, which may be any known video decoder. For example, a low bit rate video decoder according to the ITU-T recommendation H.263 or H.26L may be used, which in this invention is arranged to decode a first sub-sequence of a video sequence, at least part of the sub-sequence having been formed by coding I-frames; to decode at least a second sub-sequence of the video sequence, at least part of the second sub-sequence having been formed by coding at least P- or B-frames and at least one video frame of the second sub-sequence having been predicted from at least one video frame of the first sub-sequence. The video decoder is arranged to determine the identification and dependency data of at least the video frames comprised by the second sub-sequence of the video sequence and to reconstruct at least part of the video sequence on the basis of the dependencies of the sub-sequences.

An essential aspect in the operation of the streaming system of the invention is that the encoder and decoder are positioned at least so that the encoder is operationally connected to the streaming server and the decoder is operationally connected to the receiving terminal device. However, the different elements of the streaming system, terminal devices in particular, may include functionalities that allow two-way transfer of multimedia files, i.e. transmission and reception. The encoder and decoder can thus be implemented in the form of what it known as a video codec integrating both encoder and decoder functionalities.

It is to be noted that according to the invention the functional elements of the above described streaming system and its elements, such as the streaming server, video encoder, video decoder and terminal are preferably implemented by hardware solutions or as a combination of hardware and software. The coding and decoding methods of the invention are particularly suitable for implementation as computer software comprising computer-readable commands for executing the process steps of the invention. A preferred way of implementing the encoder and the decoder is to store them in a storage means as a program code that can be executed by a computer-like device, for example a personal computer (PC) or a mobile station, to provide coding/decoding functionalities on the device in question.

Another alternative is to implement the invention as a video signal comprising a scalably compressed video sequence which in turn comprises video frames coded according to at least a first and a second frame format, the video frames according to the first frame format being independent of other video frames, and the video frames of the second frame format being predicted from at least one of the other video frames. According to the invention, the video signal in question comprises at least a first sub-sequence, at least part of which has been formed by coding at least video frames of the first frame format; at least a second sub-sequence, at least part of which has been formed by coding at least video frames of the second frame format; and at least one video frame of the second sub-sequence having been predicted from at least one video frame of the first sub-sequence; and at least one data field that determines video frames belonging to the second sub-sequence.

It is apparent to a person skilled in the art that as technology advances the basic idea of the invention can be implemented in various ways. The invention and its embodiments are therefore not restricted to the above examples, but they may vary within the scope of the claims. 

1. A method for encoding a video sequence comprising an independent sequence of image frames, wherein all motion-compensated temporal prediction references of the independent sequence refer only to image frames within said independent sequence, the method comprising: encoding into the video sequence an indication of at least one image frame, which is the first image frame, in decoding order, of the independent sequence; encoding identifier values for the image frames according to a numbering scheme; and resetting the identifier value for the indicated first image frame of the independent sequence.
 2. A method according to claim 1, further comprising: encoding the indication into the video sequence as a separate flag included in the header of a slice.
 3. A method according to claim 1, further comprising: encoding into the video sequence an identifier value for the independent sequence.
 4. A video encoder comprising at least one processor and at least one memory including computer program code, the at least one memory and the computer program code configured to, with the at least one processor, cause the video encoder to encode a video sequence comprising an independent sequence of image frames, wherein all motion-compensated temporal prediction references of the independent sequence refer only to image frames within said independent sequence by causing the video encoder to at least: encode into the video sequence an indication of at least one image frame, which is the first image frame, in decoding order, of the independent sequence; encode identifier values for the image frames according to a numbering scheme; and reset the identifier value for the indicated first image frame of the independent sequence.
 5. A video encoder according to claim 4, wherein the video encoder is configured to encode the indication into the video sequence as a separate flag included in the header of a slice.
 6. A video encoder according to claim 4, wherein the video encoder is configured to encode into the video sequence an identifier value for the independent sequence.
 7. A computer program product, stored on a non-transitory computer readable medium and executable in a data processing device, for encoding a video sequence comprising an independent sequence of image frames, wherein all motion-compensated temporal prediction references of the independent sequence refer only to image frames within said independent sequence, the computer program product comprising: a computer program code for encoding into the video sequence an indication of at least one image frame, which is the first image frame, in decoding order, of the independent sequence; a computer code for encoding identifier values for the image frames according to a numbering scheme; and a computer code for resetting the identifier value for the indicated first image frame of the independent sequence.
 8. A method for decoding a compressed video sequence, the method comprising: decoding from the video sequence an indication of at least one image frame, which is the first image frame, in decoding order, of an independent sequence, wherein all motion-compensated temporal prediction references of the independent sequence refer only to image frames within said independent sequence; starting the decoding of the video sequence from said first image frame of the independent sequence, whereby the video sequence is decoded without prediction from any image frame decoded prior to said first image frame; decoding identifier values for image frames according to a numbering scheme; and resetting the identifier value for the indicated first image frame of the independent sequence.
 9. A method according to claim 8, wherein the indication is a separate flag included in the header of a slice.
 10. A video decoder comprising at least one processor and at least one memory including computer program code, the at least one memory and the computer program code configured to, with the at least one processor, cause the video decoder to decode a compressed video sequence, by causing the video decoder to at least: decode from the video sequence an indication of at least one image frame, which is the first image frame, in decoding order, of an independent sequence, wherein all motion-compensated temporal prediction references of the independent sequence refer only to image frames within said independent sequence; start the decoding of the video sequence from said first image frame of the independent sequence, whereby the video sequence is decoded without prediction from any image frame decoded prior to said first image frame; and decode identifier values for image frames according to a numbering scheme; and reset the identifier value for the indicated first image frame of the independent sequence.
 11. A computer program product, stored on a non-transitory computer readable medium and executable in a data processing device, for decoding a compressed video sequence, the computer program product comprising: a computer program code for decoding from the video sequence an indication of at least one image frame, which is the first image frame, in decoding order, of an independent sequence, wherein all motion-compensated temporal prediction references of the independent sequence refer only to image frames within said independent sequence; a computer program code for starting the decoding of the video sequence from said first image frame of the independent sequence, whereby the video sequence is decoded without prediction from any image frame decoded prior to said first image frame; a computer program code for decoding identifier values for image frames according to a numbering scheme; and a computer program code for resetting the identifier value for the indicated first image frame of the independent sequence. 